Korea has produced large quantities of Panax Ginseng roots which have a stimulating effect on the metabolisma of protein, lipid and nucleic acids in the body. Authors believe that the lear and trunk of Panax Ginseng might have some components possessing a similar activity to Panax Ginseng root although the quantity and quality of the functional components may be somewhat different. Therefore, this study was designed to observe the nutritional effects of diet supplemented with the leaves or trunks of Panax Ginseng. Weanling(body weight; $82{\pm}3g$) male albino rats were subjected to six different dietary groups as followings; A groups; dietary groups which were treated with steam for 30 min at $115^{\circ}C}$. B Groups; dietary groups which were not treated with steam. A-C (or B-C) dietary group; Control for A groups(or B groups) containing 99% wheat flour. A-1 (or B-1) dietary group; dietary group supplemented with 2% leaf of Panax Ginseng, which replaced 2% wheat flour of control diet. A-2 (or B-2) dietary group; dietary group supplemented with 2% trunk of Panax Ginseng, which replaced 2% wheat flour or control diet. Each group of rats was maintained with the corresponding diet for 40 days. And then they were sacrificed. The growth rate, protein efficiency ratio, and the contents of lipid and cholesterol in organs were determined. The results obtained are summarized as follows;1) The gained body weights of dietary group supplemented with 2% leaf(A-1 and B-1) or 2% trunk(A-2 and B-2) of panax Ginseng were more increased in comparison to the corresponding control group(A-C and B-C). 2) The gained body weight of each group in A-group(A-C, A-I and A-2) was higher than that or each corresponding dietary group in B-group(B-C, B-1 and B-2). 3) The protein efficiency ratios of A-1 and A-2 dietary group, and B-1 and B-2 dietary group were more improved in comparison to the corresponding control group(A-C and BC). 4) The lipid contents in the liver of A-1 and B-1 dietary groups were lower than in that of A-C and. B-C dietary group, respectively. According to the above results, it could be suggested that the nutritional value of the wheat flour can be improved by supplement of 2% leaf or 2% trunk of Panax Ginseng.
This study was carried out to investigate the effect of seasonal changes on some of the morphological and physiological characteristics, including the photosynthetic abilities and dark respiration, of young ginseng plants due to planting location under shading. The results obtained are as follows: 1. Seedlings and 2-year old plants planted in the back rows appeared to have broader leaf area, and their leaf weight greatly increased in September. Chlorophyll content was significantly reduced in September rather than in June and the plants in the back rows had more chlorophyll content than those in the front rows. 2. There was no difference in the light compensation point between the front and back rows in June, while in September the light compensation point of 2-year old ginseng leaves was much lower for plants in the back rows compared with those in the front rows. A difference in the light saturation point was not noticeable between plants in the front and back rows in June and September. But the light saturation point of 2-year old ginseng leaves at $15^{\circ}C$ was high in June, while it was high at $20^{\circ}C$ high in September. 3. Maximum photosynthetic ability was attained at $15^{\circ}C$ in June and at $20^{\circ}C$ in September. During June no significant difference in photosynthetic ability was found between plants in the front and back rows, but in September the amount of photosynthesis was significantly increased at the leaves of seedlings as well as 2-year old plants planted in the back rows. 4. The optimum temperature for maximum photosynthesis in 2-year old plants ranged from $14.0^{\circ}C$ to $14.5^{\circ}C$ in June and from $19.5^{\circ}C$ to $20.5^{\circ}C$ in September. However, the optimum temperature for maximum photosynthesis in the seedlings was from $21.2^{\circ}C$ to $21.6^{\circ}C$ in September, but a significant difference in the optimum temperature for the maximum photosynthesis in seedlings and 2-year old plants was not noticeable between the front and back rows. 5. The respiration rate was rather high in seedlings compared with 2-year old plants. During September the respiration rate in seedlings was much lower in the back rows than in the front rows. The rate of increase in the respiration of 2-year old plants was higher at September than June. The increase in respiration rate due to temperature was more significant in seedlings than 2-year old plants. 6. In September, the level of $Q_{10}$ in 2-year old plants was much lower than that found in seedlings. During June, 2-year old plants showed lower $Q_{10}$ levels at a temperature difference between $15^{\circ}C$ and $25^{\circ}C$; but in September this occurred at a temperature difference between $20^{\circ}C$ and $30^{\circ}C$.
Lee, Jong Chul;Mok, Seong Kyun;Lee, Jong Wha;Jo, Jae Seong
Korean Journal of Agricultural Science
/
v.10
no.2
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pp.235-241
/
1983
This experiment was conducted to determine the effect of soil moisture content and planting depth on the growth of 2-year old ginseng plant. The results obtained are summarized as follows; 1. When the ginseng seedlings were planted in soil by 4 to 5cm in depth, the length of leaflet and stem and the number of branch roots were significantly decreased but the stem diameter was increased. 2. Highly significant quadratic regressions were shown between soil moisture content and the growth of the stem, leaf and root of the ginseng plant. 3. Estimated amount of soil moisture for the maximum growth of the stem was 75% of field capacity, and that for length and width of the leaflet was about 65 to 66% of field capacity. Estimated soil moisture for the maximum growth of the root was about 56 to 58% of field capacity and that for increase in root weight was about 60 to 61% of field capacity. 4. Estimated soil moisture content for best growth of ginseng roots was 1 to 5% lower when the seedling was planted in 3cm depth compared with 2cm in depth. And when the amount of soil moisture was 31% of field capacity, the deep planting was adequate for good root growth. 5. Significant correlations were resulted between the dry weight of roots and the leaf length, the leaf width and the dry weight of stem and leaves. And also, significant correlations were obtained between the ratio of root dry weight to root fresh weight and the stem length, the leaf length, the leaf width and the dry weight of stem and leaves.
Panax ginseng leaf tea was developed for the functional benefit of health, preference and convenience. The leaves of 4-year-old ginseng were selected in July and August. The ginseng leaf was treated by three methods : heat processed tea(HPT), aged tea(AGT) and hot-air dried tea(DRT). The contents and compositions of their crude saponin of ginseng leaves were measured. 1. The content of crude saponin of HPT was the higher than other treatments. The content of HPT was 18.72∼18.82%, ACT 18.24∼18.29% and DRT 17.02∼17.17%. 2. The harvest time and treatment methods were not affect the composition of ginsenoside in ginseng leaf tea. The ginsenoside-Re was shown the highest value as 1.97∼2.15. And ginsenoside-Rd was 1.48∼1.79, -Rg$_1$ 1.33∼1.58 and -Rb, -Rb$_2$, -Rc in the order. 3. The content of protopanaxadiol(PD) and protopanaxatriol(PT) was shown that DRT was 1.11∼1.13, HPT 1.09~l.12 and AGT 0.92∼1.02. The content of PD and PT were shown similar result at any harvest time. 4. The contents of crude saponin extracted by hot-water at 5 min was the higher ratios in HPT and harvested in July than other treatments. The content of crude saponin of ginseng leaf harvested in July was 15.88% and HPT was 16.88%. The order of contents of ginsenoside were -Re, -Rd, -Rg$_1$, -Rb$_1$, -Rb$_2$, and - Rc. The extraction ratio of crude saponin extracted by the circulated extraction method in 8 hours and 5 min extraction were 81.74∼84.38%. And HPT of ginseng leaf harvested in July was the highest value 84.3% but the extraction ratio of ginsenoside was 78.00~88.13%. But the extraction ratio of ginsenoside was similar trend in all treatments.
Jun-Ho, Lee;Ji-Won, Yoon;Bong-Ki, Kim;Hee-Bok, Park;Kyu-Sang, Lim;Ji-Hyuk, Kim
Korean Journal of Poultry Science
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v.49
no.4
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pp.255-264
/
2022
This study was performed to investigate the effects of dietary supplementation with ginseng by-products on growth, organ development, blood biochemical profiles, immune response, and stress parameter of broilers reared in high ambient temperatures. One hundred one-day-old male chicks (Ross 308) were used. At week two, the birds were randomly allocated into five dietary groups; control (CON), 0.5% ginseng berry (GB1), 1.0% ginseng berry (GB2), 0.5% ginseng leaves and stems (GLS1), and 1.0% ginseng leaves and stems (GLS2). The temperature was maintained at 32±1℃from 9 AM to 5 PM. Growth, serum immunoglobulins and corticosterone levels were monitored and analyzed. No significant differences among groups were observed in growth. However, during the finisher period (21~35d) and overall period (7~35 d), body weight gain in all supplemented groups tended higher than CON group. Blood biochemical profiles did not significantly differ among treatment groups except in bilirubin level. Serum immunoglobulins and corticosterone level showed no significant differences among groups. IgM and IgG levels were numerically higher in GLS1 than in other groups, but the difference was not significant. Corticosterone level also tended lower in all supplemented groups than in CON group, and larger decreases were observed in groups with higher ginseng by-product concentration. In conclusion, dietary supplementation of ginseng by-products shows potential to reduce heat stress in growing broilers with no negative effect on productivity.
This study was conducted to define the optimal conditions for embryo growth during seed stratification and for breaking dormancy as well as seed germination of stratified ginseng seeds. The experiments were also carried out to detect some materials which were expected to induce seed dormancy in the ginseng seeds. The results summarized as follows; 1. The growth of embryo during seed stratification was significantly inhibited by the existence of endocarp. The fastest embryo growth was resulted at $15^{\circ}C$ and an estimated optimal temperature for embryo growth was about $18^{\circ}C$. 2. There was no significant difference between the embryo growth and germination ratio of ginseng seeds which were sown in seed bed at Aug-5 without seed stratification and that of artificial seed stratification. 3. Embryo growth and germination ratio was significantly inhibited by high temperature treatment at $30^{\circ}C$ for 24 hours or respiration stress by immersing seeds in water for 10 days or more. 4. When the seed stratification was started at $10^{\circ}C$, growth of embryo in the ginseng seeds were almost stopped. But, when the seeds were stratified first at $20^{\circ}C$ for 50 days and next at $10^{\circ}C$ for 50 days, the embryo growth was significantly promoted compared with the embryo growth in the seeds which were stratified at $20^{\circ}C$ for 100 days. 5. The successive embryo growth after seed stratification was significantly accelerated at $10^{\circ}C$ but the seeds chilled at $5^{\circ}C$ for 100 days were resulted in the highest germination ratio as well as the shortest days for germination. 6. The successive embryo growth during chilling treatment and seed germination were significantly inhibited by immersing seeds in water just before chilling treatment or during chilling treatment and by interruption of chilling treatment with raising temperature to $20^{\circ}C$ for 20 days during chilling treatment. 7. The germination ratio of ginseng seeds which finished chilling treatment was highest at $10^{\circ}C$ and 62.5% was the estimated soil moisture for the best germination of ginseng seeds. The ginseng seeds were found to require high amount of oxygen for germination. 8. Only water soluble material in homogenized ginseng seeds showed a significant inhibiting effect on the seed germination of sesame, millet and soybean. Water soluble material dissolved from undehisced ginseng seeds showed stronger inhibiting effect on the seedling growth of sesame than material from dehisced ginseng seeds. Extraction temperature did not influence the inhibiting effect of the material dissolved from ginseng seeds on the seedling growth of sesame. 9. Water soluble materials dissolved from the berry pulps, leaves, fresh roots and dried roots also showed a significant inhibiting effect on the seedling growth of sesame. 10. Water soluble materials dissolved from the ginseng seeds, leaves and fresh roots showed a significant inhibiting effect on the germination of true fungi and the growth of spawn but the growth of phytopathogenic bacteria was not. 11. Among the water soluble materials dissolved from ginseng seeds, the materials of low molecular weight less than 3,000 were resulted a significant inhibiting effect on the seedling growth of sesame and the materials of high molecular weight also showed an inhibiting effect.
The "Ginseng Pork" produced by feeding ginseng by-products can be a compatible product in the sense of increasing pork consumption and developing functional food in the international pork market. This experiment was conducted to produce "Ginseng Pork" with emphasis on growth performance and meat quality. Experiments were conducted in which 30 Landrace heads were fed with bark of ginseng root(BGR) or heating extracts ginseng leaves and stem(HEG). WB-shear force was not different among the treatment groups until 15 days of ageing, but pork fed with the 6% BGR showed a higher shear force at 20 day of storage at 4$^{\circ}C$. Cooking loss showed lower value for the 9% BGR group compared with the control group. At 15 day, the 3% and 9% BGR groups showed lower cooking losses than control. Pork groups fed HEG showed a significantly(p<0.05) lower TBARS values after 5 days of storage. As for VBN analysis, the feeding groups of 9% BGR and 5.5% HEG had significantly lower values at 5 and 20 days when compared to the other treatment groups. It might be concluded that the accumulation of ginseng saponin in the pork resulted in retarding the ageing and inhibiting the oxidation.
Sang Young Seo;Jong hyeon Cho;Chang Su Kim;Hyo Jin Kim;Min Sil An;Du Hyeon Yoon
Proceedings of the Plant Resources Society of Korea Conference
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2020.12a
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pp.62-62
/
2020
Ginseng is a shade-plant cultivated using shading facilities. However, at too low light levels, root growth is poor, and at high light levels, the destruction of chlorophyll reduces the photosynthesis efficiency due to leaf burn and early fall leaves. The ginseng has a lightsaturation point of 12,000~15,000 lux when grown at 15 to 20℃ and 9,500 lux at 25℃. This study was conducted to select the optimal light intensity of 3-year-old ginseng grown in blue-white film plastic house. The seeds were planted in the blue-white film plastic house with different light receiving rate (March 17, 2020). Between April and September, the average air temperature in the house was 20.4-20.7℃. Average soil temperature was 18.3℃-18.5℃. The chemical properties of the test soil was as follows. The pH level was 7.0-7.4, EC was 0.5-0.6 dS/m, OM was at the levels of 33.6-37.7 g/kg, P2O5 was 513.0-590.8 mg/kg, slightly higher than the allowable 400 mg/kg. The amount of light intensity, illuminance, and solar radiation in the blue-white film house was increased as the light-receiving rate increased and the amount of light intensity was found to be 9-14% compared to the open field, 8-13% illuminance and 9-14% solar irradiation respectively. The photosynthesis rate was the lowest at 3.1 µmolCO2/m2/s in the 9% light blue-white plastic house and 4.2 and 4.0 µmolCO2/m2/s in the 12% and 14% light blue-white plastic house, respectively. These results generally indicate that the photosynthesis of plants increases with the amount of light, but the ginseng has a lower light saturation point at high temperatures, and the higher the amount of light, the lower the photosynthetic efficiency. The SPAD (chlorophyll content) value decreased as the increase of light-receiving rate, and was the highest at 32.7 in 9% light blue-white plastic house. Ginseng germination started on April 11 and took 13-15 days to germinate. The overall germination rate was 82.9-85.8%. The plant height and length of stem were long in the 9% light-receiving plastic house. The diameter of stem was thick in the 12-14% light-receiving plastic house. In the 12% and 14% light-receiving plastic house, the length and diameter of taproot was long and thick, so the fresh weight of root per plant was 20 g or more, which was heavier than 16.9 g of the 9% light-receiving plastic house. The disease incidence (Alternaria blight, Gray mold and Damping-off etc.) rate were 0.9-2.7%. The incidence of Sclerotinia rot disease was 7.5-8.4%, and root rot was 0-20.0%. The incidence ratio of rusty root ginseng was 34.4-38.7% level, which was an increase from the previous year's 15% level.
This study was carried out to investigate the sea sonal changes of the contents of inhibitors in leaves and fruits of Ginseng plant during ripening. Three kinds of inhibitors in leaves and all parts of fruit, i.e., seed, sarcocarp and endocarp were recognized at the Rf 0.1, 0.4-0.6 and 0.8-1.0 zones by the bioassay of lettuce seed germination. Among them, the level of the inhibitor at the Rf 0.4-0.6 zone in leaf and seed increased most significantly in accordance with fruit ripening. The activities of three inhibitors found in endocarp gradually decreased during ripening.
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